EP1565403B1 - Procede de synthese de nanotubes de carbone - Google Patents

Procede de synthese de nanotubes de carbone Download PDF

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Publication number
EP1565403B1
EP1565403B1 EP03775902.4A EP03775902A EP1565403B1 EP 1565403 B1 EP1565403 B1 EP 1565403B1 EP 03775902 A EP03775902 A EP 03775902A EP 1565403 B1 EP1565403 B1 EP 1565403B1
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Prior art keywords
mixture
solvent
metal
metal nanoparticles
metal salts
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German (de)
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EP1565403A1 (fr
EP1565403A4 (fr
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Avetik Harutyunyan
Leonid Grigorian
Toshio Tokune
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Honda Motor Co Ltd
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Honda Motor Co Ltd
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B82NANOTECHNOLOGY
    • B82YSPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
    • B82Y30/00Nanotechnology for materials or surface science, e.g. nanocomposites
    • DTEXTILES; PAPER
    • D01NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
    • D01FCHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
    • D01F9/00Artificial filaments or the like of other substances; Manufacture thereof; Apparatus specially adapted for the manufacture of carbon filaments
    • D01F9/08Artificial filaments or the like of other substances; Manufacture thereof; Apparatus specially adapted for the manufacture of carbon filaments of inorganic material
    • D01F9/12Carbon filaments; Apparatus specially adapted for the manufacture thereof
    • D01F9/127Carbon filaments; Apparatus specially adapted for the manufacture thereof by thermal decomposition of hydrocarbon gases or vapours or other carbon-containing compounds in the form of gas or vapour, e.g. carbon monoxide, alcohols
    • D01F9/1271Alkanes or cycloalkanes
    • D01F9/1272Methane
    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01BNON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
    • C01B32/00Carbon; Compounds thereof
    • C01B32/15Nano-sized carbon materials
    • C01B32/158Carbon nanotubes
    • C01B32/16Preparation
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S977/00Nanotechnology
    • Y10S977/84Manufacture, treatment, or detection of nanostructure
    • Y10S977/842Manufacture, treatment, or detection of nanostructure for carbon nanotubes or fullerenes
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S977/00Nanotechnology
    • Y10S977/84Manufacture, treatment, or detection of nanostructure
    • Y10S977/89Deposition of materials, e.g. coating, cvd, or ald
    • Y10S977/891Vapor phase deposition

Definitions

  • the present invention relates to a method for the synthesis of carbon nanotubes.
  • Single-walled carbon nanotubes are a material with many potential applications. For example, the properties of some carbon nanotubes may allow for creation of capacitors with capacitance versus size characteristics that are not readily attainable with traditional materials. More generally, single-walled nanotubes (SWNTs) made of carbon may exhibit either metallic or semiconducting properties, depending on their diameter and crystalline structure.
  • SWNTs single-walled nanotubes
  • One current technique for synthesis of carbon nanotubes involves chemical vapor deposition (CVD) on a growth substrate containing metal nanoparticles.
  • CVD chemical vapor deposition
  • current CVD methods of carbon nanotube synthesis suffer from a lack of control over the size and shape of the nanotubes.
  • Some methods of carbon nanotube production lead to mixtures of single-walled nanotubes and multi-walled nanotubes.
  • Other methods result in production of nanotubes with variations in nanotube shape and size, leading to a lack of control over the properties of the resulting nanotubes.
  • Obtaining the metal nanoparticles for use in the growth substrate also poses difficulties. Some current techniques may produce particles of a desirable size, but with poor crystallinity or an unpredictable distribution of phases within the nanoparticles. Other techniques suffer from an inability to control the distribution of sizes around a desired nanoparticle size. Still other nanoparticle synthesis techniques require specialized equipment, long processing times, or expensive specialty chemicals.
  • WO 01/49599 is titled "High yield vapor phase deposition method for large scale single walled carbon nanotube preparation".
  • WO 01/49599 discloses a vapor phase deposition method for the preparation of single walled carbon nanotubes on an aerogel supported metal catalyst.
  • WO 01/49599 discloses that the total yield of single walled carbon nanotubes often is at least about 100 %, based the weight of the catalyst, for a reaction time of at least about 30 minutes.
  • a document by Li et at is titled "Growth of single-walled carbon nanotubes from discrete catalytic nanoparticles of various sizes", J. Phys. Chem. B, 2001, 105 (46), pp 11424-11431 .
  • the Li et al document discloses discrete catalytic nanoparticles with diameters in the range of 1-2 nm and 3-5 nm which are obtained by placing controllable numbers of metal atoms into the cores of apoferritin, and used for growth of single-walled carbon nanotube on substrates by chemical vapor deposition (CVD).
  • CVD chemical vapor deposition
  • the Li et al document discloses that nanoparticles placed on ultrathin alumina membranes, isolated single-walled carbon nanotubes are grown and directly examined by transmission electron microscopy.
  • the Li et al document discloses that by controlling the structures of catalytic nanoparticles allows the control of nanotube diameter.
  • the present invention provides a method for the synthesis of carbon nanotubes via chemical vapor deposition (CVD) using metal nanoparticles as a growth catalyst.
  • Metal nanoparticles of a controlled size distribution are dispersed in a passivating solvent along with a powdered oxide.
  • the mixture of metal nanoparticles and powdered oxide is then extracted from the passivating solvent and annealed under an inert atmosphere.
  • Nanotubes are then grown by exposing the nanoparticles to a flow of a carbon precursor gas at a temperature in the vicinity of 680°C to 900°C. Control over the size of the carbon nanotubes is achieved in part by controlling the size of the metal nanoparticles in the growth catalyst.
  • Figures 1 and 2 depict possible apparatuses for synthesizing metal nanoparticles for use in carrying out the present invention. While Figures 1 and 2 depict possible equipment selections, those skilled in the art will recognize that any suitable mixing apparatus and reflux apparatus may be used for synthesis of the nanoparticles. Although no specialized equipment is required to carry out the present invention, the components used should be suitable for use with the various embodiments of this invention. Thus, the mixing and reflux equipment should be safe for use with organic solvents and should be safe for use at the reflux temperature of the thermal decomposition reaction.
  • the various embodiments of this invention make use of metal nanoparticles having a controlled size distribution as a catalyst material for facilitating the growth of carbon nanotubes by a CVD process.
  • the metal nanoparticles having a controlled size distribution may be obtained by any suitable method.
  • the metal nanoparticles may be synthesized according to the following method involving thermal decomposition of a metal salt in a passivating solvent.
  • Reaction vessel 130 may be any suitable vessel for holding a metal salt and passivating solvent mixture during mixing and refluxing steps.
  • reaction vessel 130 may be a 500 ml glass or PyrexTM Erlenmeyer flask. Other styles of reaction vessel, such as roundbottom flasks, may also be used as long as the reaction vessel is compatible for use with the mixing and reflux apparatuses.
  • reaction vessel 130 is attached to sonicator 150. Sonicator 150 may be used to mix the contents of reaction vessel 130.
  • a suitable sonicator is the FS60 available from Fisher Scientific of Pittsburgh, PA.
  • reaction vessel 130 may be mixed by other methods, such as by using a standard laboratory stirrer or mixer. Other methods of mixing the solution will be apparent to those skilled in the art.
  • Reaction vessel 130 may also be heated during mixing by a heat source 170.
  • heat source 170 is shown as a hot plate, but other suitable means of heating may be used, such as a heating mantle or a Bunsen burner.
  • FIG. 2 depicts a reflux apparatus 200.
  • reaction vessel 130 is connected to a condenser 210.
  • Condenser 210 is composed of a tube 220 that is surrounded by a condenser jacket 230.
  • water or another coolant is circulated through condenser jacket 230 while heat is applied to reaction vessel 130.
  • the coolant may be circulated by connecting the inlet of the condenser jacket to a water faucet, by circulating a coolant through a closed loop via a pump, or by any other suitable means.
  • evaporated passivating solvent rising from reaction vessel 130 will be cooled as it passes through tube 220. This will cause the passivating solvent to condense and fall back into reaction vessel 130.
  • heat source 170 may be a hot plate, heating mantle, Bunsen burner, or any other suitable heating apparatus as will be apparent to those skilled in the art.
  • both mixing and reflux may be accomplished using a single apparatus.
  • stopper 205 may have a second opening to allow passage of the shaft of the stirring rod from a laboratory mixer or stirrer.
  • the reaction vessel may be connected to the dual mixing and refluxing apparatus. Still other embodiments of how to mix and reflux the contents of a reaction vessel will be apparent to those skilled in the art.
  • Figure 3a provides a flow diagram of the steps for preparing metal nanoparticles according to an embodiment of the present invention.
  • Figure 3a begins with preparing 310 a mixture by adding a passivating solvent and metal salt to the reaction vessel.
  • the passivating solvent is an ether.
  • the passivating solvent is a glycol ether.
  • the passivating solvent is 2-(2-butoxyethoxy)ethanol, H(OCH 2 CH 2 ) 2 O(CH 2 ) 3 CH 3 , which will be referred to below using the common name dietheylene glycol mono-n-butyl ether.
  • the metal salt will be a metal acetate.
  • Suitable metal acetates include transition metal acetates, such as iron acetate, Fe(OOCCH 3 ) 2 , nickel acetate, Ni(OOCCH 3 ) 2 , or palladium acetate, Pd(OOCCH 3 ) 2 .
  • Other metal acetates that may be used include molybdenum.
  • the metal salt may be a metal salt selected so that the melting point of the metal salt is lower than the boiling point of the passivating salt.
  • metal salt and passivating solvent are factors in controlling the size of nanoparticles produced.
  • a wide range of molar ratios here referring to total moles of metal salt per mole of passivating solvent, may be used for forming the metal nanoparticles.
  • Typical molar ratios of metal salt to passivating solvent include ratios as low as about 0.0222 (1:45), or as high as about 2.0 (2:1).
  • typical reactant amounts for iron acetate range from about 5.75x10 -5 to about 1.73x10 -3 moles (10 - 300 mg).
  • Typical amounts of diethylene glycol mono-n-butyl ether range from about 3x10 -4 to about 3x10 -3 moles (50 - 500 ml).
  • more than one metal salt may be added to the reaction vessel in order to form metal nanoparticles composed of two or more metals.
  • the relative amounts of each metal salt used will be a factor in controlling the composition of the resulting metal nanoparticles.
  • the molar ratio of iron acetate to nickel acetate is 1:2.
  • the molar ratio of a first metal salt relative to a second metal salt may be between about 1:1 and about 10:1.
  • preparing a mixture 310 may involve a series of steps, such as those shown in the flow diagram in Figure 3b.
  • Figure 3b begins with initially preparing 311 two or more mixtures of metal salt and passivating solvent in separate reaction vessels.
  • each mixture is formed by adding one metal salt to a passivating solvent.
  • the same passivating solvent is used to form each of the metal salt and passivating solvent mixtures.
  • the contents of each of the reaction vessels are mixed during initial mixing 315.
  • initial mixing 315 the contents of the reaction vessels are mixed to create substantially homogeneous mixtures.
  • the homogenous mixtures may be in the forms of mixtures, solutions, suspensions, or dispersions.
  • the contents of the reaction vessels are sonicated for 2 hours.
  • the contents of the reaction vessel may be mixed using a standard laboratory stirrer or mixer. Other methods for creating the homogeneous mixture or dispersion will be apparent to those skilled in the art.
  • the contents of the reaction vessel may be heated during initial mixing 315 in order to reduce the required mixing time or to improve homogenization of the mixture.
  • the contents of the reaction vessels are sonicated at a temperature of 80°C. After first mixing 315, the homogenous mixtures are combined 320 into a single reaction vessel to create a mixture containing all of the metal salts and passivating solvents.
  • the contents of the reaction vessel are mixed during mixing 330.
  • the contents of the reaction vessel are mixed to create a substantially homogeneous mixture of metal salt in the passivating solvent.
  • the homogenous mixture may be in the form of a mixture, solution, suspension, or dispersion.
  • the contents of the reaction vessel are mixed by sonication.
  • the contents of the reaction vessel may be mixed using a standard laboratory stirrer or mixer.
  • the contents of the reaction vessel may also be heated during mixing 330 in order to reduce the required sonication or mixing time.
  • the contents of the reaction vessel are sonicated at 80°C for two hours and then both sonicated and mixed with a conventional laboratory stirrer at 80°C for 30 minutes. In another embodiment, the contents of the reaction vessel are sonicated at room temperature for between 0.5 and 2.5 hours. Other methods for creating the homogeneous mixture will be apparent to those skilled in the art.
  • metal nanoparticles are formed during the thermal decomposition 350.
  • the thermal decomposition reaction is started by heating the contents of the reaction vessel to a temperature above the melting point of at least one metal salt in the reaction vessel. Any suitable heat source may be used including standard laboratory heaters, such as a heating mantle, a hot plate, or a Bunsen burner. Other methods of increasing the temperature of the contents of the reaction vessel to above the melting point of the metal salt will be apparent to those skilled in the art.
  • the length of the thermal decomposition 350 will be dictated by the desired size of the metal nanoparticles, as will be discussed below. Typical reaction times may range from about 20 minutes to about 2400 minutes, depending on the desired nanoparticle size.
  • the thermal decomposition reaction is stopped at the desired time by reducing the temperature of the contents of the reaction vessel to a temperature below the melting point of the metal salt.
  • the reaction is stopped by simply removing or turning off the heat source and allowing the reaction vessel to cool.
  • the reaction may be quenched by placing the reaction vessel in a bath. Note that in this latter embodiment, the temperature of the quench bath may be above room temperature in order to prevent damage to the reaction vessel.
  • the contents of the reaction vessel are refluxed during the heating step.
  • a standard reflux apparatus may be used, such as the one depicted in Figure 2 .
  • water or another coolant
  • condensing jacket 230 Vapors rising from the passivating solvent are cooled as they pass through tube 220, leading to condensation of the passivating solvent vapors.
  • the condensed passivating solvent then falls back into the reaction vessel. This recondensation prevents any significant loss of volume of the passivating solvent during the thermal decomposition reaction.
  • the relative ratio of metal to passivating solvent stays substantially constant throughout the reaction.
  • the size and distribution of metal nanoparticles produced by the present invention may be verified by any suitable method.
  • One method of verification is transmission electron microscopy (TEM).
  • TEM transmission electron microscopy
  • a suitable model is the Phillips CM300 FEG TEM that is commercially available from FEI Company of Hillsboro, OR.
  • TEM micrographs of the metal nanoparticles 1 or more drops of the metal nanoparticle/passivating solvent solution are placed on a carbon membrane grid or other grid suitable for obtaining TEM micrographs.
  • the TEM apparatus is then used to obtain micrographs of the nanoparticles that can be used to determine the distribution of nanoparticle sizes created.
  • Figures 4a - 4e and 5a - 5e depict histograms of particle size distributions for iron nanoparticles created under several conditions.
  • the particle size distributions represent iron nanoparticles made by mixing iron acetate and diethylene glycol mono-n-butyl ether in a reaction vessel to form a homogeneous mixture. The contents of the reaction vessel were then refluxed at the boiling point of diethylene glycol mono-n-butyl ether (231°C) for the time period specified in each figure.
  • the figures also note the concentration of the metal acetate in the passivating solvent.
  • concentrations are specified as ratios of milligrams of iron acetate per milliliter of passivating solvent, but note that these ratios are coincidentally similar to the molar ratios, due to the similar molecular weights of iron acetate and diethylene glycol mono-n-butyl ether (173.84 g/mol versus 162.23 g/mol) and the fact that the density of diethylene glycol mono-n-butyl ether is close to 1.
  • Figures 4a- 4e depict histograms from a series of reactions where the ratio of milligrams of iron acetate to milliliters of diethylene glycol mono-n-butyl ether was held constant at 1:1.5 while varying the length of the reflux at the reaction temperature. For comparison purposes, the histograms have been normalized so that the area under the histogram bars in each figure equals 100.
  • Figure 4a depicts results from the shortest reaction time of 20 minutes at the boiling point of diethylene glycol mono-n-butyl ether (231°C).
  • Figure 4a 20 minutes of thermal decomposition reaction time leads to a narrow distribution of particle sizes centered on 5 nm.
  • Figures 4b - 4e depict similar histograms for increasing amounts of reaction time. As seen in the figures, increasing the reaction time leads to an increase in the average particle size. Additionally, Figures 4d and 4e indicate that at the longest reflux times (300 minutes and 1200 minutes), the width of the particle size distribution also increases.
  • Figures 5a - 5e provide additional results from thermal decomposition reactions with varying concentrations at a constant reaction time of 1200 minutes, or 20 hours. Note that even the lowest ratio of iron acetate to passivating solvent results in an average particle size of 10 nm. These results indicate that both low concentrations and short reaction times are required to achieve the smallest particle sizes.
  • secondary dispersion 370 begins by introducing particles of a powdered oxide, such as aluminum oxide (Al 2 O 3 ) or silica (SiO 2 ), into the reaction vessel after the thermal decomposition reaction.
  • a powdered oxide such as aluminum oxide (Al 2 O 3 ) or silica (SiO 2 )
  • Al 2 O 3 powder with 1-2 ⁇ m particle size and having a surface area of 300 - 500 m 2 /g is available from Alfa Aesar of Ward Hill, MA.
  • enough powdered oxide is added to achieve a desired weight ratio between the powdered oxide and the initial amount of metal used to form the metal nanoparticles. In an embodiment, this weight ratio is between roughly 10:1 and roughly 15:1. For example, in an embodiment involving 100 mg of iron acetate as the starting material, roughly 32 mg of the starting material corresponds to iron. Thus, roughly 320 to 480 mg of powdered oxide would be introduced into the solution. Other materials suitable for use as the powdered oxide will be apparent to those skilled in the art.
  • the mixture is mixed to again form a homogenous mixture or dispersion of metal nanoparticles and powdered oxide in the passivating solvent.
  • the homogenous mixture or dispersion may be formed using sonicator 150, a standard laboratory stirrer or mixer, or any other suitable method.
  • the mixture may be both sonicated and mixed using a conventional laboratory mixer or stirrer to form the homogenous mixture or dispersion.
  • the mixture of metal nanoparticles, powdered oxide, and passivating solvent is first sonicated at roughly 80°C for 2 hours. The mixture is then both sonicated and mixed with a laboratory stirrer at 80°C for 30 minutes.
  • extraction 390 includes heating the homogenized mixture to a temperature where the passivating solvent has a significant vapor pressure. This temperature is maintained until the passivating solvent evaporates, leaving behind the metal nanoparticles deposited in the pores of the Al 2 O 3 .
  • the homogenous dispersion is heated to 231 °C, the boiling point of the passivating solvent, under an N 2 flow. The temperature and N 2 flow are maintained until the passivating solvent is completely evaporated. After evaporating the passivating solvent, the powdered oxide and metal nanoparticles are left behind on the walls of the reaction vessel as a film or residue. In embodiments involving Al 2 O 3 as the powdered oxide, the film will be black.
  • the powdered oxide serves two functions during the above extraction process. Because of the porous, high surface area nature of the powdered oxide, the metal nanoparticles will settle in the pores of the powdered oxide during secondary dispersion 370. Settling in the pores of the powdered oxide physically separates the metal nanoparticles, thus preventing agglomeration of the metal nanoparticles during extraction 390. This effect is complemented by the amount of powdered oxide used. As noted above, in an embodiment the weight ratio of metal nanoparticles to powdered oxide is between about 1:10 and 1:15. The relatively larger amount of powdered oxide in effect serves to further separate or 'dilute' the metal nanoparticles as the passivating solvent is removed.
  • metal nanoparticles are highly reactive, in part due to their high surface area to volume ratio.
  • the metal nanoparticles will have a tendency to oxidize.
  • iron nanoparticles extracted from a passivating solvent by heating the passivating solvent to 230°C in the presence of oxygen will be at least partially converted to iron oxide nanoparticles.
  • the present invention relates to the synthesis of metal nanoparticles, it is understood that the metal nanoparticles may subsequently become partially oxidized after the completion of the thermal decomposition reaction.
  • the methods described above may be used to produce metal nanoparticles with a controlled size distribution.
  • the metal nanoparticles comprise nanoparticles between roughly 3 nm and roughly 7nm in size, such as the distribution depicted in Figure 4a .
  • the metal nanoparticles comprise nanoparticles between roughly 5 nm and roughly 10 nm in size, such as the distribution depicted in Figure 4b .
  • the metal nanoparticles comprise nanoparticles between roughly 8 nm and roughly 16 nm in size, such as the distribution depicted in Figure 4d .
  • FIG. 6 depicts a flow chart for using metal nanoparticles to grow carbon nanotubes according to an embodiment of the present invention.
  • the metal nanoparticle and powdered oxide film is removed from the reaction vessel and ground to create a fine powder.
  • the grinding step increases the available surface area of the mixture.
  • the mixture is ground with a mortar and pestle. Other methods of increasing the surface area of the mixture will be apparent to those of skill in the art.
  • catalyst preparation 610 comprises obtaining a previously prepared mixture of metal nanoparticles and powdered oxide.
  • catalyst preparation 610 comprises adding previously prepared metal nanoparticles and a powdered oxide to a suitable volume of passivating solvent. The metal nanoparticles and powdered oxide are then homogenously dispersed, extracted from the passivating solvent, and processed to increase the effective surface area as described above. Other methods for preparing the metal nanoparticle and powdered oxide mixture will be apparent to those skilled in the art.
  • furnace 700 may be any conventional laboratory furnace capable of providing flows of inert and reagent gases during heating.
  • the Carbolite model TZF 12/65/550 is a suitable horizontal 3-zone furnace for carrying out some embodiments of the present invention.
  • quartz tube 710 is placed inside furnace 700.
  • quartz tube 710 is 100 cm long and 5 cm in diameter.
  • a quartz boat (not shown) containing the material to be heated is placed inside of quartz tube 710.
  • Gas inlets 730, 731, and 732 provide flows of inert and reagent gases during operation of the furnace.
  • catalyst annealing 630 comprises annealing the mixture of the powdered oxide and metal nanoparticles at a temperature between roughly 400°C and roughly 550°C under a flow of 100 standard cubic centimeters per minute (sccm) composed of a reducing reagent, such as hydrogen (H 2 ), and an inert gas, such as helium (He).
  • a reducing reagent such as hydrogen (H 2 )
  • an inert gas such as helium (He).
  • the gas flow is composed of 10% H 2 and 90% He.
  • the annealing step lasts for roughly 1 - 2 hours. It is believed that exposing the metal nanoparticle and powdered oxide mixture to a reducing atmosphere during annealing will at least partially reverse any oxidation of the metal nanoparticles that may have occurred.
  • the mixture is annealed at a temperature between roughly 500°C and 550°C under a flow of 100 sccm of argon (Ar).
  • Catalyst annealing 630 may also optionally include a second annealing process. In an embodiment involving this optional second annealing process, after the first annealing process the mixture of metal nanoparticles and powdered oxide is ground again with a mortar and pestle. The mixture is then returned to the furnace for the second annealing.
  • nanotube growth 650 begins by heating the metal nanoparticle and powdered oxide mixture in a furnace to a deposition temperature between roughly 680°C and roughly 900°C under a gas flow of 100 sccm of Ar.
  • the deposition temperature is selected to be between roughly 800°C and roughly 900°C. Once the desired deposition temperature is achieved, the flow of Ar gas is increased to between about 200 sccm and about 400 sccm.
  • a carbon precursor gas flow of between about 30 sccm and 50 sccm is also introduced into the furnace.
  • the carbon precursor gas is methane (CH 4 ).
  • Introduction of the carbon precursor gas flow begins the deposition process for the formation of carbon nanotubes.
  • the deposition temperature, inert gas flow, and carbon gas flow are maintained for between about 30 minutes and about 60 minutes.
  • the flow of the carbon precursor gas is turned off and the furnace is allowed to cool to room temperature under the Ar flow.
  • the amount of time required for this cooling step will depend on the furnace used. For example, for the furnace described above this cooling step takes approximately 4 hours.
  • ethylene (C 2 H 4 ) may be used instead of CH 4 as the carbon precursor gas. When using ethylene, deposition temperatures toward the lower end of the range should be used.
  • the end product of nanotube growth 650 is a black soot containing amorphous carbon, powdered oxide, metal nanoparticles, and carbon nanotubes.
  • some or all of the other materials in the end product may need to be removed from this mixture during nanotube extraction 670.
  • the carbon nanotubes can be extracted from the other materials using a series of selective cleaning steps. First, the mixture of powdered oxide, amorphous carbon, metal nanoparticles, and carbon nanotubes is washed in a concentrated hydrogen fluoride solution (HF). In an embodiment, the mixture is immersed in 98% HF for 1 minute at 25°C.
  • HF concentrated hydrogen fluoride solution
  • the powdered oxide is Al 2 O 3 or SiO 2
  • the powdered oxide will dissolve in the HF without affecting the other components of the mixture.
  • the mixture can be transferred to an HF compatible container prior to this step, as 98% HF will etch quartz, and thus may damage a quartz boat.
  • the mixture is removed from the HF solution and rinsed with water to remove excess HF.
  • the mixture now contains only amorphous carbon, metal nanoparticles, and carbon nanotubes.
  • the amorphous carbon is removed next by returning the mixture to the furnace and selectively oxidizing the amorphous carbon, such as by a temperature programmed oxidation method.
  • Temperature programmed oxidation is used to identify the appropriate temperature for removing the amorphous carbon due to the fact that the thermal oxidation characteristics of the mixtures vary between successive nanotube formation processes.
  • the temperature programmed oxidation begins by heating a small portion of the amorphous carbon, metal nanoparticle, and carbon nanotube mixture in the furnace in the presence of dry air. As the temperature in the furnace rises, the desorption of species from the mixture is monitored. The first desorption peak should correspond to the volitalization of amorphous carbon. The remainder of the mixture is then introduced into the furnace and heated in dry air at the temperature corresponding to the first desorption peak.
  • the remaining mixture of metal nanoparticles and carbon nanotubes is allowed to cool to room temperature.
  • the mixture is then washed in a strong acid such as hydrochloric acid, nitric acid, or aqua regia to dissolve the metal nanoparticles.
  • the mixture of metal nanoparticles and carbon nanotubes is immersed in 6 M HCl.
  • the acid used to remove the metal nanoparticles may vary depending on the composition of the nanoparticles.
  • the carbon nanotubes are rinsed with water to remove any remaining acid, leaving the carbon nanotubes ready for use.
  • TEM transmission electron microscopy
  • Figure 8 provides an example of Raman spectra at an excitation frequency of 785 mn for carbon nanotubes produced according to an embodiment of the present invention.
  • the three spectra represent carbon nanotubes grown on iron nanoparticle substrates with various nanoparticle size distributions.
  • the 'breathing' modes of the nanotubes are visible in the range of 100 to 300 cm -1 .
  • the spectra presented in Fig. 8 provide an example of Raman spectra for use in identifying carbon nanotubes. Because a given excitation frequency will only interact with certain sizes of nanotubes, full characterization of a carbon nanotube sample would require running multiple Raman spectra at different excitation frequencies.
  • carbon nanotubes may be grown with diameters ranging from roughly 0.7 nm to greater than 1.7 nm. Additionally, the chirality of the nanotubes also depends on the initial nanoparticle size. Control over the size and chirality of the resulting nanotubes is important for controlling whether the nanotubes have metallic or semiconducting characteristics.
  • dotted lines have been included to indicate potential breathing mode peak locations in each of the three spectra. Note that all three of the spectra exhibit a nanotube breathing mode peak at approximately 175 cm -1 . It is believed that this common peak represents nanotubes grown on nanoparticles of roughly 7 nm in size, a nanoparticle size common to all three of the spectra. This provides an example of how control of nanoparticle size can be used to select for certain types of nanotubes.

Claims (20)

  1. Procédé de production de nanotubes de carbone, comprenant les étapes de :
    fourniture d'un mélange composé essentiellement d'un ou de plusieurs sels métalliques et d'un solvant ;
    mélange du mélange dudit un ou plusieurs sels métalliques et dudit solvant ;
    chauffage du mélange dudit un ou plusieurs sels métalliques et dudit solvant à une température supérieure au point de fusion d'au moins un dudit un ou plusieurs sels métalliques et maintien de la température supérieure au point de fusion d'au moins un dudit un ou plusieurs sels métalliques pour former des nanoparticules métalliques ;
    ajout d'un oxyde en poudre au mélange des nanoparticules métalliques et du solvant ;
    mélange du mélange des nanoparticules métalliques, de l'oxyde en poudre, et du solvant ;
    extraction des nanoparticules métalliques et de l'oxyde en poudre du solvant ;
    recuit des nanoparticules métalliques et de l'oxyde en poudre ;
    chauffage des nanoparticules métalliques et de l'oxyde en poudre à une température supérieure à une température de dépôt nécessaire pour former des nanotubes de carbone ; et
    exposition des nanoparticules métalliques à un gaz précurseur de carbone tout en maintenant la température au-dessus de la température de dépôt nécessaire pour former des nanotubes de carbone.
  2. Procédé selon la revendication 1, dans lequel le recuit du mélange des nanoparticules métalliques et de l'oxyde en poudre comprend l'étape de chauffage du mélange des nanoparticules métalliques et de l'oxyde en poudre entre 400°C et 550°C en présence d'un écoulement de gaz composé de 10 % de H2 et de 90 % de He.
  3. Procédé selon la revendication 1, dans lequel le recuit du mélange des nanoparticules métalliques et de l'oxyde en poudre comprend l'étape de chauffage du mélange de nanoparticules métalliques et d'oxyde en poudre entre 500°C et 550°C en présence d'un écoulement de gaz inerte.
  4. Procédé selon la revendication 1, dans lequel ledit un ou plusieurs sels métalliques sont des acétates métalliques de transition.
  5. Procédé selon la revendication 1, dans lequel au moins un dudit un ou plusieurs sels métalliques est une substance choisie dans le groupe composé d'acétate de fer, d'acétate de palladium, d'acétate de nickel, et d'acétate de molybdène.
  6. Procédé selon la revendication 1, dans lequel l'oxyde en poudre est choisi dans le groupe composé d'oxyde d'aluminium et d'oxyde de silicium.
  7. Procédé selon la revendication 1, dans lequel la température de dépôt se situe entre 680°C et 900°C.
  8. Procédé selon la revendication 1, dans lequel le solvant est un éther de glycol.
  9. Procédé selon la revendication 1, dans lequel le solvant est un 2-(2-butoxyéthoxy)éthanol.
  10. Procédé selon la revendication 1, dans lequel le chauffage du mélange dudit un ou plusieurs sels métalliques et dudit solvant comprend l'étape de reflux du mélange dudit un ou plusieurs sels métalliques et dudit solvant.
  11. Procédé selon la revendication 10, dans lequel le mélange dudit un ou plusieurs sels métalliques et dudit solvant est reflué au point d'ébullition dudit solvant.
  12. Procédé selon la revendication 1, dans lequel le rapport molaire du mélange dudit un ou plusieurs sels métalliques et dudit solvant est situé entre 2:1 et 1:45.
  13. Procédé selon la revendication 1, dans lequel le mélange du mélange dudit un ou plusieurs sels métalliques et dudit solvant comprend l'étape de mélange du mélange dudit un ou plusieurs sels métalliques et desdits solvants pour former un mélange homogène.
  14. Procédé selon la revendication 1, dans lequel le mélange du mélange des nanoparticules métalliques, de l'oxyde en poudre, et du solvant comprend l'étape de mélange du mélange des nanoparticules métalliques, de l'oxyde en poudre, et du solvant pour former un mélange homogène.
  15. Procédé selon la revendication 1, dans lequel le rapport molaire du métal à l'oxyde en poudre est situé entre 1:10 et 1:15.
  16. Procédé selon la revendication 1, dans lequel la température du mélange dudit un ou plusieurs sels métalliques et dudit solvant est maintenue à une température supérieure au point de fusion d'au moins un dudit un ou plusieurs sels métalliques pour une durée située entre 20 minutes et 2400 minutes.
  17. Procédé selon la revendication 1, dans lequel le gaz précurseur de carbone est du méthane.
  18. Procédé selon la revendication 1, comprenant en outre l'étape d'extraction des nanotubes de carbone des produits formés pendant ladite étape d'exposition.
  19. Procédé selon la revendication 1, dans lequel ladite étape d'exposition comprend l'exposition des nanoparticules métalliques au gaz précurseur de carbone pour une durée située entre 30 minutes et 60 minutes.
  20. Procédé selon la revendication 1, dans lequel ledit solvant est un solvant pour un ou plusieurs sels métalliques.
EP03775902.4A 2002-11-26 2003-11-26 Procede de synthese de nanotubes de carbone Expired - Lifetime EP1565403B1 (fr)

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
US10/304,317 US7214361B2 (en) 2002-11-26 2002-11-26 Method for synthesis of carbon nanotubes
US304317 2002-11-26
PCT/JP2003/015085 WO2004048262A1 (fr) 2002-11-26 2003-11-26 Procede de synthese de nanotubes de carbone

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EP1565403A1 EP1565403A1 (fr) 2005-08-24
EP1565403A4 EP1565403A4 (fr) 2008-12-24
EP1565403B1 true EP1565403B1 (fr) 2015-07-15

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JP (1) JP4583928B2 (fr)
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WO (1) WO2004048262A1 (fr)

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JP5194514B2 (ja) * 2007-03-29 2013-05-08 富士通セミコンダクター株式会社 基板構造及びその製造方法
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JP4583928B2 (ja) 2010-11-17
US7214361B2 (en) 2007-05-08
US20040101467A1 (en) 2004-05-27
EP1565403A1 (fr) 2005-08-24
AU2003283835A1 (en) 2004-06-18
EP1565403A4 (fr) 2008-12-24
WO2004048262A1 (fr) 2004-06-10
JP2006507207A (ja) 2006-03-02

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